Ex Parte Janis et alDownload PDFPatent Trial and Appeal BoardSep 18, 201815005650 (P.T.A.B. Sep. 18, 2018) Copy Citation UNITED STA TES p A TENT AND TRADEMARK OFFICE APPLICATION NO. FILING DATE 15/005,650 01/25/2016 102469 7590 09/20/2018 PARKER JUSTISS, P.C./Nvidia 14241 DALLAS PARKWAY SUITE 620 DALLAS, TX 75254 FIRST NAMED INVENTOR PekkaJanis UNITED STATES DEPARTMENT OF COMMERCE United States Patent and Trademark Office Address: COMMISSIONER FOR PATENTS P.O. Box 1450 Alexandria, Virginia 22313-1450 www .uspto.gov ATTORNEY DOCKET NO. CONFIRMATION NO. 14-HE-0407-US02 5146 EXAMINER YU,LIHONG ART UNIT PAPER NUMBER 2631 NOTIFICATION DATE DELIVERY MODE 09/20/2018 ELECTRONIC Please find below and/or attached an Office communication concerning this application or proceeding. The time period for reply, if any, is set in the attached communication. Notice of the Office communication was sent electronically on above-indicated "Notification Date" to the following e-mail address(es): docket@pj-iplaw.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD Ex parte PEKKA JANIS, TOMMI KOIVISTO, and KARI HAMALAINEN Appeal2018-003328 Application 15/005,650 1 Technology Center 2600 Before DENISE M. POTHIER, JOHN P. PINKERTON, and JAMES W. DEJMEK, Administrative Patent Judges. DEJMEK, Administrative Patent Judge. DECISION ON APPEAL Appellants appeal under 35 U.S.C. § 134(a) from a Final Rejection of claims 11-17, 19, and 20. Appellants have withdrawn claims 1-10 from consideration. See Appellants' Resp. (filed December 27, 2016) (electing claims 11-20). The Examiner has objected to claim 18 as being dependent upon a rejected base claim, but has indicated claim 18 would be allowable if rewritten in independent form. Final Act. 9. We have jurisdiction over the remaining pending claims under 35 U.S.C. § 6(b ). We affirm-in-part. 1 Appellants identify Nvidia Corporation as the real party in interest. Br. 3. Appeal2018-003328 Application 15/005,650 STATEMENT OF THE CASE Introduction Appellants' disclosed and claimed invention generally relates to a base station in a communication system providing "an elevation beamforming transmission based on a set of elevation precoding matrix indicator offsets in an elevation codebook." Spec. ,r,r 2-5, Abstract. According to the Specification, cell-specific elevation beamforming relates to a particular down-tilt of a base station antenna array. Spec. ,r 12. It is desirable to set the down-tilt such that the array gain is maximized for user devices close to the base station while also avoiding excessive inter-cell interference with our (neighboring) cell sites. Spec. ,r 12-13. Further, "[ w ]hen an applied down-tilt or a transmit beamformer on a physical resource block is optimized for each user equipment instead of a whole user equipment distribution, system performance improvement may be obtained." Spec. ,r 14. In a disclosed embodiment (e.g., a frequency division duplex system), the user device performs channel measurements based on a reference signal and provides feedback to the base station. Spec. ,r 15. The base station transmits data using an elevation beamforming based on the received feedback information from the user device. See Fig. 3. Claims 11 and 12 are exemplary of the subject matter on appeal and are reproduced below with the disputed limitations emphasized in italics: 11. A method of operating a communications system having a cellular structure, comprising: selecting a set of elevation precoding matrix indicator (PM!) offsets in an elevation codebook for elevation beamforming based on reducing inter-cell interference for neighboring cells by a base station located within a cell of the cellular structure; 2 Appeal2018-003328 Application 15/005,650 transmitting the set of elevation precoding matrix indicator (PMI) offsets and a set of reference signals for channel quality and inter-cell interference measurements from the base station to user equipment within the cell; selecting a channel quality indicator (CQI) and a corresponding one of the set of elevation precoding matrix indicator (PMI) offsets based on the channel quality and inter- cell interference measurements by the user equipment; reporting the selected channel quality indicator (CQI) and elevation precoding matrix indicator (PMI) offset by the user equipment to the base station; and transmitting data using an elevation beamforming based on the selected elevation precoding matrix indicator (PMI) offset at a data rate based on the selected channel quality indicator (CQI) from the base station to the user equipment. 12. The method as recited in Claim 11 wherein the channel quality indicator (CQI) is based on a ratio of a physical downlink shared channel (PDSCH) energy per resource element (EPRE) and the reference signal including a cell-specific reference signal (CRS) or a channel state information reference signal (CSI-RS) EPRE. The Examiner's Rejections 1. Claims 11-15 and 20 stand rejected under 35 U.S.C. § 103 as being unpatentable over Thomas et al. (US 2014/0355702 Al; Dec. 4, 2014) ("Thomas"). Final Act. 3-7. 2. Claims 16 and 19 stand rejected under 35 U.S.C. § 103 as being unpatentable over Thomas and Wennstrom (US 8,238,225 B2; Aug. 7, 2012). Final Act. 7-8. 3. Claim 17 stands rejected under 35 U.S.C. § 103 as being unpatentable over Thomas and Han et al. (US 8,767,661 B2; July 1, 2014) ("Han"). Final Act. 9. 3 Appeal2018-003328 Application 15/005,650 ANALYSIS 2 Claims 11, 16, and 17 Appellants assert the Examiner erred in finding Thomas teaches "selecting a set of elevation precoding matrix indicator (PMI) offsets ... based on reducing inter-cell interference for neighboring cells," as recited in claim 11. Br. 5-7. In particular, Appellants argue Thomas describes a network architecture of a coverage cell and a capacity booster cell. Br. 6 ( citing Thomas ,r,r 31, 42). Because the capacity booster cell is located within the coverage cell (see Thomas ,r 31, Fig. 2), Appellants contend Thomas is directed to reducing interference within a single cell, and not inter-cell interference for neighboring cells. The Examiner finds, and we agree, Thomas teaches selecting PMis from a codebook (used for elevation beamforming) to "result in lower interference by the coverage cell on the capacity booster cell." Ans. 3--4 ( quoting Thomas ,r 51 ); see also Thomas ,r 42. The Examiner notes, as do we, that Thomas teaches an issue affecting interference between the coverage cell and capacity booster cell is "enhanced inter-cell interference coordination (eICIC)." Ans. 4; Thomas ,r 42. Contrary to Appellants' arguments, the Examiner explains that "there are areas in the coverage cell that are not included in the capacity booster cell (Thomas: Fig. 2 and paragraph 0031 ), and those areas in the coverage cell would interfere with 2 Throughout this Decision, we have considered the Appeal Brief, filed November 20, 2017 ("Br."); the Examiner's Answer, mailed December 6, 2017 ("Ans."); and the Final Office Action, mailed May 18, 2017 ("Final Act."), from which this Appeal is taken. Appellants did not file a Reply Brief. 4 Appeal2018-003328 Application 15/005,650 the capacity booster cell to cause 'inter-cell interference for neighboring cells."' Ans. 4. Based on the Examiner's findings and explanation, we are not persuaded by Appellants' arguments. Accordingly, we sustain the Examiner's rejection of claim 11. Regarding dependent claims 16 and 17, Appellants argue the cited references (Wennstrom and Han) do not remedy the deficiencies alleged relating to the Examiner's rejection of claim 11. Br. 14--16. Because we do not find the Examiner's rejection of independent claim 11 to be in error, we are not persuaded of Examiner error by Appellants' arguments. Thus, we sustain the Examiner's rejection of claims 16 and 17. Claims 12 and 13 Claim 12 depends from claim 11 and recites "the channel quality indicator (CQI) is based on a ratio of a physical downlink shared channel (PDSCH) energy per resource element (EPRE) and the reference signal including a cell-specific reference signal (CRS) or a channel state information reference signal (CSI-RS) EPRE." Appellants acknowledge the cited portions of Thomas mention the terms CQI, PDSCH, and CSI-RS, but that Thomas uses these terms separately. Br. 8. In particular, Appellants argue Thomas is silent as to a CQI feedback signal being based on a ratio of PDSCH EPRE and a CSI-RS EPRE. Br. 8. In response, the Examiner cites to paragraphs 72 through 7 6 in Thomas, finding Thomas teaches the recited elements (i.e., CQI, PDSCH, and CSI-RS) and that "[i]t would have been obvious to one ordinary skill in the art to draw a comparison between the channel PDSCH and the reference 5 Appeal2018-003328 Application 15/005,650 signal CSI-RS because one is corresponding to the other." Ans. 4--5; see also Final Act. 5 ( citing Thomas ,r,r 72, 75-76). Here, even upon review of Thomas' s cited passages, the Examiner has not provided sufficient evidence or technical reasoning in support of the stated conclusion. Accordingly, we do not sustain the Examiner's rejection of claim 12. Additionally, we do not sustain the Examiner's rejection of claim 13, which depends therefrom. Claim 14 Claim 14 depends from claim 11 and recites "the precoding matrix indicator offset corresponds to a common offset applied to all precoding matrix indicator values in the elevation codebook." Appellants assert that paragraph 4 7 of Thomas, as identified by the Examiner in the rejection (see Final Act. 10), is silent as to a common offset applied to all precoding matrix indicator values in an elevation codebook. Br. 10. We note, as does the Examiner, that Thomas describes "[a] PMI value may correspond to a single codebook index or to multiple codebook indexes." Thomas ,r 48 (emphasis added); Ans. 6. Thus, Thomas teaches, or reasonably suggests, that the PMI value may correspond to all codebook index values. Accordingly, we sustain the Examiner's rejection of claim 14. Claim 15 Claim 15 recites that "the precoding matrix indicator offset corresponds to a precoding matrix indicator offset separately applied to each precoding matrix indicator in order to enable biasing of a resulting channel 6 Appeal2018-003328 Application 15/005,650 quality indicator in a direction-dependent beamfonning manner." Appellants assert Thomas, as relied on by the Examiner, fails to teach applying an offset to PMI ("let alone applying it to each PMI) to enable biasing of a resulting CQI in a direction-dependent beamforming manner. Br. 11-12. As an initial matter, we note that "[ a ]n intended use or purpose usually will not limit the scope of the claim because such statements usually do no more than define a context in which the invention operates." Boehringer Ingelheim Vetmedica, Inc. v. Schering-Plough Corp., 320 F.3d 1339, 1345 (Fed. Cir. 2003). Notwithstanding, Appellants' arguments do not apprise us of Examiner error. As with claims 11 and 14 ( discussed above), the Examiner finds Thomas teaches the PMI offset corresponds to a precoding matrix indicator offset separately applied to each precoding matrix indicator. See, e.g., Final Act. 3-5 (citing Thomas ,r,r 42, 47--48, 50- 51, 61 ); Ans. 4---6. Further, the Examiner finds Thomas teaches the PMI offset enables biasing of a resulting CQI in a direction-dependent beamforming manner. Final Act. 6 ( citing Thomas ,r,r 41, 46). Thomas describes the use of elevation-port beamforming weights to direct the direction of the beam. Thomas ,r 41, Fig. 8 (illustrating various down-tilt angles). Further, Thomas describes the base station could limit a user device to feedback CQI and PMI "for only a restricted codebook set which steers away from the edge of [the] cell" based on the base station's knowledge of the user device location (i.e., a directional bias). Thomas ,r 7 4. Accordingly, we sustain the Examiner's rejection of claim 15. 7 Appeal2018-003328 Application 15/005,650 Claim 19 Claim 19 depends from claim 11 and recites: wherein the precoding matrix indicator offset is one of N possible values and is signaled as a length K*log2(N) vector of bits b, where each set of log2(N) bits corresponds to a precoding matrix indicator offset value and the location of the set of log2(N) bits within the vector of bits b corresponds to a precoding matrix indicator, a set of precoding matrix indicators or a phase difference value dependent on K, wherein the elevation codebook contains K distinct rank-I precoders. As relied on by the Examiner, Wennstrom teaches log2(P) bits are required for control signaling to indicate to a user device which precoding matrix is used because the size of the base unit cookbook is P matrices. Wennstrom, col. 4, 11. 33-37; see also Final Act. 7-8. Appellants argue Wennstrom "is silent as to the location of the set of log2(P) bits and the rank- I precoders." Br. 15. In response, the Examiner states "[ e Jach precoding matrix is an independent vector, thus a rank-I precoding matrix." Ans. 7. Here, the Examiner has not provided sufficient evidence or technical reasoning in support of the stated finding and conclusion that W ennstrom teaches or suggests the recited "rank-I precoders." Accordingly, we do not sustain the Examiner's rejection of claim 19. Claim 20 Claim 20 depends from claim 11 and recites "the precoding matrix indicator offset is applied as a power offset in a Physical Downlink Shared Channel (PDSCH) transmission, where PDSCH precoding is applied according to a reported elevation precoding matrix indicator." (Emphasis 8 Appeal2018-003328 Application 15/005,650 added.) Appellants assert the cited portions of Thomas fail to teach or suggest applying a PMI offset as a power offset. Br. 13. In response, the Examiner states Thomas teaches applying a PMI offset in a PD SCH transmission and because "[ a ]ccording to mathematics, a power is the number of times a certain number is to be multiplied by itself ... [Thomas teaches the] PMI offset has a power of one." Ans. 6-7. When construing claim terminology during prosecution before the Office, claims are to be given their broadest reasonable interpretation consistent with the Specification, reading claim language in light of the Specification as it would be interpreted by one of ordinary skill in the art. In re Am. Acad. of Sci. Tech. Ctr., 367 F.3d 1359, 1364 (Fed. Cir. 2004). However, the broadest reasonable interpretation differs from the broadest possible interpretation. In re Smith Int'!, Inc., 871 F.3d 1375, 1383 (Fed. Cir. 2017). The correct inquiry in giving a claim term its broadest reasonable interpretation in light of the specification is "an interpretation that corresponds with what and how the inventor describes his invention in the specification, i.e., an interpretation that is 'consistent with the specification."' Smith, 871 F.3d at 1382-83 (quoting In re Morris, 127 F.3d 1048, 1054 (Fed. Cir. 1997)). The Examiner's construction of "power"-and, more specifically, "power offset"-is not consistent with the Specification or with how an ordinarily skilled artisan would understand the term in the context of the claims in light of the Specification. See, e.g., Spec. ,r,r 32-33, 40. The term relates to an offset to transmission power. Accordingly, we do not sustain the Examiner's rejection of claim 20. 9 Appeal2018-003328 Application 15/005,650 DECISION We affirm the Examiner's decision rejecting claims 11 and 14--1 7. We reverse the Examiner's decision rejecting claims 12, 13, 19, and 20. No time period for taking any subsequent action in connection with this appeal may be extended under 37 C.F.R. § 1.136(a)(l )(iv). See 37 C.F.R. § 4I.50(f). AFFIRMED-IN-PART 10 Copy with citationCopy as parenthetical citation
